壁面貼附材料與空氣負離子對室內生物氣膠控制效率的影響

Yi-Chen Hsiao; 蕭儀禎

請用此 Handle URI 來引用此文件： http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/6540

完整後設資料紀錄

DC 欄位	值	語言
dc.contributor.advisor	李慧梅(Whei-May Lee)
dc.contributor.author	Yi-Chen Hsiao	en
dc.contributor.author	蕭儀禎	zh_TW
dc.date.accessioned	2021-05-17T09:14:31Z	-
dc.date.available	2012-08-19
dc.date.available	2021-05-17T09:14:31Z	-
dc.date.copyright	2012-08-19
dc.date.issued	2012
dc.date.submitted	2012-08-15
dc.identifier.citation	Agranovski, V., Ristovski, Z., Hargreaves, M., Blackall, P. J., & Morawska, L. (2003). Real-time measurement of bacterial aerosols with the UVAPS: performance evaluation. Journal of Aerosol Science, 34(3), 301-317. Amend, A. S., Seifert, K. A., Samson, R., & Bruns, T. D. (2010). Indoor fungal composition is geographically patterned and more diverse in temperate zones than in the tropics. Proceedings of the National Academy of Sciences, 107(31), 13748-13753. Andersson, M., Mikkola, R., Kroppenstedt, R., Rainey, F., Peltola, J., Helin, J., Salkinoja-Salonen, M. (1998). The mitochondrial toxin produced by Streptomyces griseus strains isolated from an indoor environment is valinomycin. Applied and environmental microbiology, 64(12), 4767-4773. Banerjee, M., Mallick, S., Paul, A., Chattopadhyay, A., & Ghosh, S. S. (2010). Heightened Reactive Oxygen Species Generation in the Antimicrobial Activity of a Three Component Iodinated Chitosan−Silver Nanoparticle Composite. Langmuir, 26(8), 5901-5908 Bolashikov, Z. D., & Melikov, A. K. (2009). Methods for air cleaning and protection of building occupants from airborne pathogens. Building and Environment, 44(7), 1378-1385. Carrera, M., Zandomeni, R. O., Fitzgibbon, J., & Sagripanti, J. L. (2007). Difference between the spore sizes of Bacillus anthracis and other Bacillus species. Journal of Applied Microbiology, 102(2), 303-312. Caruana, D. J. (2011). Detection and analysis of airborne particles of biological origin: present and future. Analyst, 136(22), 4641-4652. Chen, G., Driks, A., Tawfiq, K., Mallozzi, M., & Patil, S. (2010). Bacillus anthracis and Bacillus subtilis spore surface properties and transport. Colloids and Surfaces B: Biointerfaces, 76(2), 512-518. Chen, P. S., & Li, C. S. (2005). Bioaerosol characterization by flow cytometry with fluorochrome. Journal of Environmental Monitoring ,7(10), 950-959. Cox, C. S., & Wathes, C. M. (1995). Bioaerosols handbook. Boca Raton: Lewis Publishers. Deacon, J. W. (1997). Modern mycology (Vol. 7): Wiley-Blackwell. Dharmage, Bailey, Raven, Mitakakis, Thien, Forbes,. Walters. (1999). Prevalence and residential determinants of fungi within homes in Melbourne, Australia. Clinical & Experimental Allergy, 29(11), 1481-1489. Fernández Rodríguez, S., Tormo Molina, R., Silva Palacios, I., & Gonzalo Garijo, Á. (2011). Two sampling methods for the Petri dish detection of airborne fungi. Grana, 50(3), 202-207. Fletcher, L., Gaunt, L., Beggs, C., Shepherd, S., Sleigh, P. A., Noakes, C., & Kerr, K. (2007). Bactericidal action of positive and negative ions in air. BMC microbiology, 7(1), 32-40. Fletcher, L., Noakes, C., Sleigh, P., Beggs, C., & Shepherd, S. (2008). Air ion behavior in ventilated rooms. Indoor and Built Environment, 17(2), 173-182. Foster, H., Ditta, I., Varghese, S., & Steele, A. (2011). Photocatalytic disinfection using titanium dioxide: spectrum and mechanism of antimicrobial activity. Applied Microbiology and Biotechnology, 90(6), 1847-1868. Fröhlich-Nowoisky, J., Pickersgill, D. A., Després, V. R., & Pöschl, U. (2009). High diversity of fungi in air particulate matter. Proceedings of the National Academy of Sciences, 106(31), 12814-12819. Gravesen, S., Larsen, L., Gyntelberg, F., & Skov, P. (1986). Demonstration of Microorganisms and Dust in Schools and Offices. Allergy, 41(7), 520-525. Gravesen, S., Nielsen, P. A. & Nielsen K. F. (1997) “Microfungi in water damaged buildings”, SBI Report Number 282, Danish Building Research Institute, Copenhagen: Denmark. Green, B. J., Tovey, E. R., Beezhold, D. H., Perzanowski, M. S., Acosta, L. M., Divjan, A. I., & Chew, G. L. (2009). Surveillance of fungal allergic sensitization using the fluorescent halogen immunoassay. Journal de Mycologie Médicale / Journal of Medical Mycology, 19(4), 253-261. Grinshpun, S. A. (2011). Biological Aerosols. Aerosols‐Science and Technology, 379-406. Guo, H., Lee, S. C., Chan, L. Y., & Li, W. M. (2004). Risk assessment of exposure to volatile organic compounds in different indoor environments. Environmental Research, 94(1), 57-66. Hardin, B. D., Kelman, B. J., & Saxon, A. (2003). Adverse human health effects associated with molds in the indoor environment. Journal of occupational and environmental medicine/American College of Occupational and Environmental Medicine, 45(5), 470-478. Hill, S. S., Shaw, B. R., & Wu, A. H. B. (2001). The clinical effects of plasticizers, antioxidants, and other contaminants in medical polyvinylchloride tubing during respiratory and non-respiratory exposure. Clinica Chimica Acta, 304(1–2), 1-8. Kolarž, P. M., Filipović, D. M., & Marinković, B. P. (2009). Daily variations of indoor air-ion and radon concentrations. Applied Radiation and Isotopes, 67(11), 2062-2067. Kondo, F., Ikai, Y., Goto, T., Ito, Y., Oka, H., Nakazawa, H., Torii, S. (2007). Two sensitive sick-building syndrome patients possibly responding to p-dichlorobenzene and 2-Ethyl-1-hexanol: Case Report. Journal of health science, 53(1), 119-123. Korpi, A., Järnberg, J., & Pasanen, A. L. (2009). Microbial volatile organic compounds. Critical Reviews in Toxicology, 39(2), 139-193. Larsen, T., Frisvad, J., Samson, R., Flannigan, B., Flannigan, M., Verhoeff, A., Hoekstra, E. (1994). Production of volatiles and presence of mycotoxins in conidia of common indoor penicillia and aspergilli. Health implications of fungi in indoor environments.,pp. 251-279. Laza, V. (2009). Enhancing the Human Reactivity by Using the Negative Air Ions Generators. International Conference on Advancements of Medicine and Health Care through Technology. 26, 151-156. Lee, B. U. (2011). Life Comes from the Air: A Short Review on Bioaerosol Control. Aerosol and Air Quality Research, 11, 921-927. Lee, S. A., Willeke, K., Mainelis, G., Adhikari, A., Wang, H., Reponen, T., & Grinshpun, S. A. (2004). Assessment of Electrical Charge on Airborne Microorganisms by a New Bioaerosol Sampling Method. Journal of Occupational and Environmental Hygiene, 1(3), 127-138. Li, C. S., & Hsu, L. Y. (1997). Airborne fungus allergen in association with residential characteristics in atopic and control children in a subtropical region. Archives of Environmental Health: An International Journal, 52(1), 72-79. Li, C. S., Hsu, L. Y., Chou, C. C., & Hsieh, K. H. (1995). Fungus allergens inside and outside the residences of atopic and control children. Archives of Environmental Health: An International Journal, 50(1), 38-43. Jung, J. H., Park, S. Y., Lee, J. E., Lee, B. U., & Bae, G. N. (2012). Distinguishing Biotic and Abiotic Particles Using an Ultraviolet Aerodynamic Particle Sizer for Real-Time Detection of Bacterial Bioaerosols. Journal of Gynecologic Surgery, 37, 39. Luts, A., Parts, T.-E., Laakso, L., Hirsikko, A., Grönholm, T., & Kulmala, M. (2009). Some air electricity phenomena caused by waterfalls: Correlative study of the spectra. Atmospheric Research, 91(2–4), 229-237. Mandal, J., & Brandl, H. (2011). Bioaerosols in Indoor Environment-A Review with Special Reference to Residential and Occupational Locations. Open Environmental & Biological Monitoring Journal, 4, 83-96. Marambio-Jones, C., & Hoek, E. (2010). A review of the antibacterial effects of silver nanomaterials and potential implications for human health and the environment. Journal of Nanoparticle Research, 12(5), 1531-1551. Max, H. g., Mervi, H.-K., Janet, M., & Maire, H. (2004). Bioaerosols Aerosols Handbook: CRC Press. Meklin, T., Husman, T., Vepsäläinen, A., Vahteristo, M., Koivisto, J., Halla‐Aho, J., Nevalainen, A. (2002). Indoor air microbes and respiratory symptoms of children in moisture damaged and reference schools. Indoor Air, 12(3), 175-183. Mendis, D. A., Rosenberg, M., & Azam, F. (2000). A note on the possible electrostatic disruption of bacteria. Plasma Science, IEEE Transactions on, 28(4), 1304-1306. Michel, O. (2000). Systemic and local airways inflammatory response to endotoxin. Toxicology, 152(1-3), 25-30. Mikkola, R., Andersson, M. A., Teplova, V., Grigoriev, P., Kuehn, T., Loss, S., Veijalainen, P. (2007). Amylosin from Bacillus amyloliquefaciens, a K+ and Na+ channel-forming toxic peptide containing a polyene structure. Toxicon, 49(8), 1158-1171. Mohr, A., Hurst, C., Crawford, R., Garland, J., Lipson, D., Mills, A., & Stetzenbach, L. (2007). Fate and transport of microorganisms in air. Manual of environmental microbiology(Ed. 3), 961-971. Mudarri, D., & Fisk, W. J. (2007). Public health and economic impact of dampness and mold. Indoor Air, 17(3), 226-235. Muhič, S., & Butala, V. (2006). Effectiveness of personal ventilation system using relative decrease of tracer gas in the first minute parameter. Energy and Buildings, 38(5), 534-542. Nakane, H., Asami, O., Yamada, Y., & Ohira, H. (2002). Effect of negative air ions on computer operation, anxiety and salivary chromogranin A-like immunoreactivity. International Journal of Psychophysiology, 46(1), 85-89. Otsuki, T., Takahashi, K., Mase, A., Kawado, T., Kotani, M., Maeda, M., Chen, Y. (2009). The biological effects of negatively-charged indoor air conditions. Kawasaki Medical Journal, 35(3), 205-214. P. De Nuntiis, O. M., P.Mandrioli,G Ranalli ,C. Sorlini. (2003). monitoring the biological aerosol. Cultural heritage and aerobiology. Park, C. W., Yoon, K. Y., Kim, Y. D., Park, J. H., & Hwang, J. (2011). Effects of condensational growth on culturability of airborne bacteria: Implications for sampling and control of bioaerosols. Journal of Aerosol Science, 42(4), 213-223. Pelaez, M., Nolan, N. T., Pillai, S. C., Seery, M. K., Falaras, P., Kontos, A. G., Dionysiou, D. D. (2012). A review on the visible light active titanium dioxide photocatalysts for environmental applications. Applied Catalysis B: Environmental 125(0), 331-349. Pestka, J. J., Yike, I., Dearborn, D. G., Ward, M. D. W., & Harkema, J. R. (2008). Stachybotrys chartarum, Trichothecene Mycotoxins, and Damp Building–Related Illness: New Insights into a Public Health Enigma. Toxicological Sciences, 104(1), 4-26. Pietarinen, V.-M., Rintala, H., Hyvarinen, A., Lignell, U., Karkkainen, P., & Nevalainen, A. (2008). Quantitative PCR analysis of fungi and bacteria in building materials and comparison to culture-based analysis. Journal of Environmental Monitoring, 10(5), 655-663. Pitkäranta, M., Meklin, T., Hyvärinen, A., Paulin, L., Auvinen, P., Nevalainen, A., & Rintala, H. (2008). Analysis of fungal flora in indoor dust by ribosomal DNA sequence analysis, quantitative PCR, and culture. Applied and environmental microbiology, 74(1), 233-244. Poortinga, A. T.; Bos, R.; Norde, W.; Busscher, H. J., Electric double layer interactions in bacterial adhesion to surfaces. Surface Science Reports 2002, 47, (1),3-32. Qian, J., Hospodsky, D., Yamamoto, N., Nazaroff, W. W., & Peccia, J. (2012). Size-resolved emission rates of airborne bacteria and fungi in an occupied classroom. Indoor Air, 22(4),339-351. Qiu, X., Miyauchi, M., Sunada, K., Minoshima, M., Liu, M., Lu, Y., . . . Hashimoto, K. (2011). Hybrid CuxO/TiO2 Nanocomposites As Risk-Reduction Materials in Indoor Environments. ACS Nano, 6(2), 1609-1618. Quadros, M. E., & Marr, L. C. (2010). Environmental and human health risks of aerosolized silver nanoparticles. Journal of the Air & Waste Management Association, 60(7), 770-781. Redlich, C. A., Sparer, J., & Cullen, M. R. (1997). Sick-building syndrome. The Lancet, 349(9057), 1013-1016. Ross, M. A., Curtis, L., Scheff, P. A., Hryhorczuk, D. O., Ramakrishnan, V., Wadden, R. A., & Persky, V. W. (2000). Association of asthma symptoms and severity with indoor bioaerosols. Allergy, 55(8), 705-711. Schweizer, C., Edwards, R. D., Bayer-Oglesby, L., Gauderman, W. J., Ilacqua, V., Juhani Jantunen, M., Kunzli, N. (2006). Indoor time-microenvironment-activity patterns in seven regions of Europe. J Expos Sci Environ Epidemiol, 17(2), 170-181. Sekimoto, K., & Takayama, M. (2011). Observations of different core water cluster ions Y−(H2O)n (Y = O2, HOx, NOx, COx) and magic number in atmospheric pressure negative corona discharge mass spectrometry. Journal of Mass Spectrometry, 46(1), 50-60. Silver, S., Phung, L., & Silver, G. (2006). Silver as biocides in burn and wound dressings and bacterial resistance to silver compounds. Journal of Industrial Microbiology & Biotechnology, 33(7), 627-634. Skalny, J. D., Mikoviny, T., Matejcik, S., & Mason, N. J. (2004). An analysis of mass spectrometric study of negative ions extracted from negative corona discharge in air. International Journal of Mass Spectrometry, 233(1–3), 317-324. Skromulis, A., & Noviks, G. (2012). Atmospheric light air ion concentrations and related meteorologic factors in Rezekne city, Latvia. Journal of Environmental Biology, 33, 455-462. Spengler, J. D. (2012). Climate change, indoor environments, and health. Indoor Air, 22(2), 89-95. Stetzenbach, L., Hurst, C., Crawford, R., Garland, J., Lipson, D., & Mills, A. (2007). Introduction to aerobiology. Manual of environmental microbiology(Ed. 3), 925-938. Stout, J. E., & Yu, V. L.(1997). Legionellosis. New England Journal of Medicine, 337(10), 682-687. Straus, D. C. (2011). The possible role of fungal contamination in sick building syndrome. Frontiers in bioscience (Elite edition), 3, 562. Su, H. L., Chou, C. C., Hung, D. J., Lin, S. H., Pao, I., Lin, J. H., Lin, J. J. (2009). The disruption of bacterial membrane integrity through ROS generation induced by nanohybrids of silver and clay. Biomaterials, 30(30), 5979-5987. Su, H. L., Lin, S. H., Wei, J. C., Pao, I. C., Chiao, S. H., Huang, C. C., Lin, S. Z. & Lin, J. J. (2011). Novel Nanohybrids of Silver Particles on Clay Platelets for Inhibiting Silver-Resistant Bacteria. PloS ONE, 6(6), e21125. Tuomainen, A., Seuri, M., & Sieppi, A. (2004). Indoor air quality and health problems associated with damp floor coverings. International Archives of Occupational and Environmental Health, 77(3), 222-226. Tyagi, A. K., Nirala, B. K., Malik, A., & Singh, K. (2008). The effect of negative air ion exposure on Escherichia coli and Pseudomonas fluorescens. Journal of Environmental Science and Health, Part A, 43(7), 694-699. Van Lancker, F., Adams, A., Delmulle, B., De Saeger, S., Moretti, A., Van Peteghem, C., & De Kimpe, N. (2008). Use of headspace SPME-GC-MS for the analysis of the volatiles produced by indoor molds grown on different substrates. Journal of Environmental Monitoring, 10(10), 1127-1133. Wålinder R, Ernsgård L, Gullstrand E, Johansson G, Norbäck D, Venge P. et al. 1999. Acute effects of experimental exposure to four volatile compounds associated with water-damaged buildings and microbial growth. In: Proceedings of Indoor Air '99, Vol.2, 8–13 August 1999, Edinburgh, Scotland. Watford, UK:Building Research Establishment Ltd, 606–611. Wang, R.-M., Wang, J.-F., Wang, X.-W., He, Y.-F., Zhu, Y.-F., & Jiang, M.-L. (2011). Preparation of acrylate-based copolymer emulsion and its humidity controlling mechanism in interior wall coatings. Progress in Organic Coatings, 71(4), 369-375. Wei, D.-L., Chen, J.-H., Jong, S.-C., & Shen, H.-D. (1993). Indoor airborne Penicillium species in Taiwan. Current Microbiology, 26(3), 137-140. WHO (1983). Indoor air pollutants: exposure and health effects. EURO Reports and Studies, 78, 1-42. WHO (2005) Housing: Sick Building Syndrome (Pamphlet No. 2)，Copenhagen, World Health Organization Regional Office for Europe World Health Organization (2009). WHO Guidelines on Indoor Air Quality: Dampness and Mould. Copenhagen, WHO Regional Office for Europe. ( http://www.euro.who.int/InformationSources/Publications/Catalogue/20090629_4) Wicklow, D., & Shotwell, O. (1983). Intrafungal distribution of aflatoxins among conidia and sclerotia of Aspergillus flavus and Aspergillus parasiticus. Canadian journal of microbiology, 29(1), 1-5. Wu, C. C., Lee, G. W. M., Cheng, P., Yang, S., & Yu, K. P. (2006). Effect of wall surface materials on deposition of particles with the aid of negative air ions. Journal of Aerosol Science, 37(5), 616-630. Wu, C. F., & Lin, W. H. (2012). Designing a Negative Air Ions Distribution Pattern for Human Health in a House Garden by Using Geostatistical Approach and a Negative Air Ion Generates Experiment. Applied Mechanics and Materials, 121, 2648-2652. Yamada, R., Yanoma, S., Akaike, M., Tsuburaya, A., Sugimasa, Y., Takemiya, S., Imada, T. (2006). Water-generated negative air ions activate NK cell and inhibit carcinogenesis in mice. Cancer Letters, 239(2), 190-197. Zhang, Q., Damit, B., Welch, J., Park, H., Wu, C.-Y., & Sigmund, W. (2010). Microwave assisted nanofibrous air filtration for disinfection of bioaerosols. Journal of Aerosol Science, 41(9), 880-888. 于台珊、何雨芳(2007)。醫療院所中央空調系統生物氣膠濃度特性調查研究。.行政院勞工委員會勞工安全衛生研究所計畫報告(編號IOSH95-H312)。王首文(2009)。壁面材質對室內環境中空氣負離子控制懸浮微粒影響之研究。臺灣大學環境工程學研究所碩士論文。包翊絹(2008)。奈米銀脫層黏土之抗菌機制及應用。中興大學生命科學研究所碩士論文。江哲銘、邵文正(2009)。擴大健康綠建材性能與效益評估計畫。內政部建築研究所。吳佩芝(2010)。室內生物性污染物之預防與空氣品質維護。室內空氣品質管理-黴害污染改善研習會，行政院環保署環境檢驗局主辦。吳佩芝、蘇慧貞、李家偉、曾昭衡、張立德(2011)。室內空氣品質標準檢討及自主管理診斷機制建立與推動。行政院環境保護署專案計畫(編號EPA-98-FA11-03-D151)。吳致呈、顏麗凰(2004)。森林林相與瀑布區之空氣正負離子特性探討，第八屆全國大專院校登山運動研討會論文集。吳致呈(2006)。空氣負離子控制室內空氣污染物之研究。臺灣大學環境工程學研究所博士論文。林文海、黃彬芳(2007)。大眾運輸工具之生物氣膠特性暴露調查。行政院勞工委員會勞工安全衛生研究所計畫報告(編號IOSH96-H101)。林江珍(2009)。層狀天然黏土分散奈米銀粒子新組成之安全性、抑制細菌生長機制及促進傷口癒合應用之研究。台灣大學促進產學合作先導性研究計畫. 林江珍、王映樵、董睿軒、蔡韋政(2009)。新型梳狀雙性高分子及其黏土插層複合型分散劑合成與應用於奈米顏料粒子之分散研究。行政院國家科學委員會專題研究計畫成果報告(編號NSC 95-2221-E-002-207-MY3)。林秀鴻(2010)。奈米銀脫層黏土抗菌機制之探討。中興大學生命科學研究所碩士論文。林振宏(2011)。中藥塗佈電漿改質聚丙烯不織布之抑菌活性探討。中原大學土木工程研究所碩士論文。林毅(2011)。電漿改質濾材塗佈聚苯胺去除生物氣膠之研究。中原大學土木工程研究所碩士論文。林翰君(2011)。低溫電漿改質棉織物塗佈中藥萃取物對抑菌研究之影響。中原大學土木工程研究所碩士論文。洪達任(2007)。含高濃度奈米銀粒子的脫層黏土之抗菌能力分析。中興大學生命科學研究所碩士論文。洪明瑞、曾昱菱、陳瑞鈴、李文忠(2008)。主動型綠建材的健康概念與發展趨勢。技師月刊，51， 68-81。洪粕宸(2011)。醫療院所空氣品質及通風情形與感染性氣膠分佈硏究。行政院勞工委員會勞工安全衛生研究所計畫報告(編號IOSH99-H312)。紀碧芳(2003)。受黴菌污染建材上之黴菌種類研究。成功大學環境醫學研究所碩士論文。婁嘉玲(2005)。紫外光與光觸媒濾材對生物氣膠殺菌效率之研究。臺灣大學環境工程學研究所碩士論文。張靜文(2002)。空氣中嗜肺性退伍軍人菌殺菌效能評估。行政院勞工委員會勞工安全衛生研究所計畫報告(編號IOSH91-H371)。張振平(2008)。作業環境非游離輻射-紫外線為害評估技術探。行政院勞工委員會勞工安全衛生研究所計畫報告(編號IOSH96-H309)。張勝善(2009)。抗靜電纖維及應用。臺灣人纖工業會訊，62，8-18。陳彥潔(2009)。奈米碳管產生空氣負離子裝置控制生物氣膠效率空間分布之研究。臺灣大學環境工程學研究所碩士論文。曾國瑋(2006)。奈米銀濾材處理生物氣膠之研究。臺灣大學環境工程學研究所碩士論文。黃小林、蔡政賢(2010)。應用低溫高週波電漿於室內生物氣膠控制之研究。行政院國家科學委員會計畫報告(編號NSC96-2221-E041-007-MY3)。黃建賓(2008)。奈米碳管空氣負離子產生裝置控制生物氣膠之研究。臺灣大學環境工程學研究所碩士論文。葉純宜、林明瀅、陳小妮、王復德(2005)。紫外線殺菌效能探討。感染控制雜誌，15(5)，293-300。楊心豪(2005)。帶電濾材對室內懸浮微粒去除效能之研究。臺灣大學環境工程學研究所博士論文。楊心豪(2009)。森林環境負離子空氣保健指標建立之研究。行政院國家科學委員會計畫(編號NSC97-2221-E464-001)。楊心豪、翁堉翔(2009)。中藥-黃連淬取物抗菌濾材之研發。行政院國家科學委員會計畫(編號NSC97-2622-E464-001-CC3)。楊心豪、陳林祈(2011)。應用抗菌胜肽濾材去除生物氣膠之研究。行政院國家科學委員會計畫(編號NSC100-2622-E464-001-CC3)。劉芸汶(2003)。一般辦公大樓空氣及灰塵中活性真菌濃度與病態大樓症候群之相關性探討。國立成功大學環境醫學研究所碩士論文。潘致弘、張靜文(2008)。醫療院所真菌菌屬對員工健康影響評估研究。行政院勞工委員會勞工安全衛生研究所研究報告(編號IOSH96-M304)。潘致弘、張靜文(2009)。醫療院所細菌與真菌對員工健康影響評估研究。行政院勞工委員會勞工安全衛生研究報告(編號IOSH97-M304)。蔡榮賢(2003)。不同職業場所中真菌暴露評估。臺北醫學大學公共衛生研究所碩士論文。鄭尊仁、李崇德、趙馨、蘇大成、郭育良(2007)。微粒空氣污染特性、毒性和健康風險之研究。環保署/國科會空污防制科研合作計畫(編號NSC 96-EPA-Z-002- 002)。. 鍾金湯、劉仲康(1997)。緬懷一位濟世救人的外科醫師─李斯特。科學月刊，28(330)。羅時麒，姚志廷(2008)。濕熱氣候建材防黴性能評估之研究。內政部建築研究所自行研究報告。蘇明德(2007)。銀的自述。科學發展，420，52 ~ 57。蘇慧貞(2002)。室內/室外空氣汙染物之國民健康風險評估及管制成本效益分析。行政院環境保護署專案計畫報告(編號EPA-98-FA11-03-D151)。蘇慧貞(2003)。居住環境中生物性污染之生命週期與健康風險研究(I)。行政院國科會研究報告(編號NSC90-2621-Z006-006)。室內空氣中總細菌數檢測方法NIEA E301.11C( 97年12月23).取自：http://www.niea.gov.tw/niea/LIVE/E30111C.htm 室內空氣中總真菌數檢測方法NIEA E401.11C( 97年12月23).取自： http://www.niea.gov.tw/niea/LIVE/E40111C.htm
dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/6540	-
dc.description.abstract	許多研究證實負離子能控制室內生物氣膠，本研究除運用負離子控制技術外，設計運用聚丙烯不織布做為壁面貼附材料，並附加具殺菌效能之奈米矽片銀於材料上，貼附於內側直徑38cm，內側柱長79cm，體積約90L之橫向圓柱狀實驗艙，並於氣流入口相對應端設置以不鏽鋼針為電極之空氣負離子產生裝置，電壓設定3.1KV，電流控制於<0.01mA。藉由材料貼附壁面與否、貼附材料噴附奈米矽片銀與否、負離子產生裝置開啟與否等各種組合，偵測施放於實驗艙中的四種生物氣膠－E. coli(細胞體)、B. subtilis(孢子體)、C. famata(細胞體)、P.citrinum(孢子體)的濃度變化狀況。生物氣膠濃度以SKC Biosampler採樣，經培養法計算菌落數換算取得。生物氣膠濃度數據另經計算可得控制效率及增進效率並藉以分析比較。實驗呈現的結果顯示各種處理方式對E. coli的控制效率依序為僅開啟負離子(29.2%)、僅有聚丙烯不織布貼附材料(23.7%)、布材貼附艙壁搭配負離子(9.7%)、布材噴附奈米矽片銀(7.7%)。布材噴附奈米矽片銀並搭配負離子不具效果，各種處理方式比較可見同壁材有搭配負離子時，效率較差； B. subtilis的控制效率差異較大，僅開啟負離子時效果可達32.2%，同壁材搭配負離子時，效率較佳，其中，貼附材含矽片銀時，搭配施放負離子，效果可增進27.0%；C. famata的控制效率在壁面貼有聚丙烯不織布時，無論有無開啟負離子裝置，皆優於未貼附不織布(噴附奈米矽片銀且無開啟負離子裝置時除外)，其中以僅貼附聚丙烯不織布之控制效率最佳，可達31.4%，其他處理方式效率接近，介於18.4%~24.1%，僅貼附材含矽片銀無效果，但搭配使用負離子，效率可達20.4%；P. citrinum控制效率接近，介於21.3%~41.0%，效果最佳為僅開啟負離子時，各種貼附材料搭配使用負離子裝置時，效果均比僅含貼附材時略降約5~8%。各種菌種最佳的控制效果仍以僅使用負離子最佳，只有 C. famata明顯不同於其他三者，在僅有壁面聚丙烯不織布環境下控制效果最好。綜而言之，壁面貼附材質的差異會影響生物氣膠控制效率；奈米矽片銀噴附於貼附材料，對壁面材質控制生物氣膠增進效率有限；含奈米矽片銀之貼附材料，可配合負離子的施放以增進生物氣膠控制效率(對E. coli、P. citrinum無效)；相同壁面貼附材質，開啟負離子產生裝置與否，會影響生物氣膠控制效率(E. coli、P. citrinum會降低，B. subtilis會增高)；負離子對生物氣膠控制效率明顯高於壁面貼附材時，負離子對此壁面材質的控制效率會有所貢獻(B. subtilis)；艙內高濃度負離子會影響不同壁面貼附材的控制效率(負電荷累積形成複雜狀況)；生物氣膠特性影響控制效率。	zh_TW
dc.description.abstract	It has been proved that negative air ions can control the indoor bioaerosols. In addition to renew this technology, in this study, we designed to use a polypropylene non-woven materials(PP-filter) as a wall attached material, and sprayed the bactericidal material–AgNPs/NSP(silver nonoparticles/nonoscale silicate platelets) onto the PP-filter. The PP-filter(AgNPs/NSP or non-AgNPs/NSP) was applied to the inner surface of a test chamber, and the ionizer was kept at 3.1 kV and <0.01 mA. Four bioaerosols－Escherichia coli(E. coli), Bacillus subtilis , Candida famata(C. famata), (B. subtilis) endospores, and the spores of Penicillium citrinum(P. citrinum), were used in this study. Bioaerosols were collected by SKC Biosampler and cultured for plate counts. Besides, we calculated the control efficiency and the enhanced efficiency. This study which investigated the control efficiency of various treatments on E. coli in decreasing order is treated with the ionizer alone(29.2%), PP-filter attached materials alone(23.7%), and the PP-filter with negative ions (9.7%), PP-filter with AgNPs/NSP (7.7%). However, PP-filter with AgNPs/NSP and the ionizer used did not raise up the efficiency .The results showed the poor efficiency when the PP-filter (AgNPs/NSP or non-AgNPs/NSP) attected in the chamber with the ionizer. We got the great differences in control efficiency of B. subtilis. The results showed the best control efficiency which is about B. subtilis up to 32.2% was treated by negative air ions. This study showed better enhanced efficiency when the same wall material was treated with negative air ions, the enhanced efficiency can be improved to 27.0%; We showed the better control efficiency about C. famata which was treated with PP-filter (AgNPs/NSP or non-AgNPs/NSP) than stainless steel, no matter the ionizer opened or not. The best control efficiency which is up to 31.4% about C. famata was treated with PP-filter (non-AgNPs/NSP),and we had the close control efficiency of other methods, ranging from 18.4% to 24.1%, except PP-filter (AgNPs/NSP). But, if PP-filter (AgNPs/NSP) was used with negative ionizer, than, 20.4%, the higher control efficiency can be obtained; the results indicated that the control efficiency of P. citrinum is between 21.3% and 41.0%, the best is only treated with negative ionizer. We got worse control efficiency when PP-filter (AgNPs/NSP or non- AgNPs/NSP) was used with the negative ionizer than those without negative ionizer. Different from the others ,we had the best control efficiency on C. famata which is treated with PP-filter (non- AgNPs/NSP) without negative air ions. The following is a summary of our conclusions. The control effectiveness of PP-filter is different to the PP-filter which contains AgNPs/NSP ; the study showed the poor enhanced efficiency when AgNPs/NSP was sprayed on the PP-filter, but if the metods was treated with the negative air ion, the control efficiency could be enhanced(not including E. coli and P. citrinum); when we pasted the same material on the wall, the negative ion ionizer was turned on or not, will affect the control efficiency of bioaerosol (the control efficiency of E.coli and P. citrinum would reduced ,and B. subtilis increased); when the control efficiency of the bioaerosols which were treated with negative air ions is significantly higher than the wall attached material, it was contribute to the enhanced efficiency of negative air ion when the bioaerosols was treated with negative air ion and wall attached material in the chamber (B. subtilis).The control efficiency of the bioaerosols which were controlled by wall attached materials would be affected by higher concentration of negative air ions(it would become a complex situation when negative ions were accumulated to the wall); bioaerosol characteristics affect the control efficiency.	en
dc.description.provenance	Made available in DSpace on 2021-05-17T09:14:31Z (GMT). No. of bitstreams: 1 ntu-101-P98541204-1.pdf: 2796330 bytes, checksum: b9fff6456c346e06f7f9604a8d4fe17f (MD5) Previous issue date: 2012	en
dc.description.tableofcontents	摘要 I 目錄 V 圖目錄 VIII 表目錄 XI 符號說明 XIII 第1章緒論 1 1-1 研究緣起 1 1-2 研究目的 3 1-3 研究內容與方法 3 1-4 研究流程 4 第2章文獻回顧 5 2-1 室內生物氣膠 5 2-1-1 生物氣膠來源 8 2-1-2 常見於室內的生物氣膠 11 2-1-3 生物氣膠對人類生活的影響 14 2-1-4 生物氣膠採樣鑑定 16 2-2 室內空氣品質維護與控制 18 2-2-1 細菌及真菌濃度標準或建議值 18 2-2-2 抗菌材料應用 19 2-2-3 奈米銀抗菌材料 21 2-2-3-1 銀奈米化之發展 21 2-2-3-1 奈米矽片銀 24 2-2-4 室內生物氣膠控制技術 27 2-2-4-1 稀釋 28 2-2-4-2 過濾 28 2-2-4-3 紫外光 29 2-2-4-4 光觸媒 29 2-2-4-5 離子 29 2-2-4-6 其他控制技術 30 2-2-5 空氣負離子運用於控制生物氣膠 31 2-2-5-1 空氣負離子來源及產生方式 31 2-2-5-2 空氣負離子基本特性與影響因子 33 2-2-5-3 空氣負離對人類健康的影響 35 2-2-5-4 空氣負離子對室內生物氣膠的控制機制與效能 36 第3章實驗設備與方法 37 3-1 實驗系統設備及材料 37 3-1-2 實驗設備 41 3-1-3 實驗菌種培養方法 44 3-1-4 生物氣膠產生單元 48 3-1-5 室內環境模擬及生物氣膠控制單元 49 3-1-5-1 實驗艙內空間位置標示 49 3-1-5-2 貼附艙壁材質處理及貼附實驗艙方式 49 3-1-6 負離子產生單元及濃度監測設備 52 3-1-7 生物氣膠採樣單元 52 3-1-8 前置實驗 52 3-1-8-1 生物氣膠初始濃度測試及實驗艙氣膠混合度測試 52 3-1-8-2 生物氣膠採樣間隔及採樣時間測試 53 3-1-8-3 負離子產生單元穩定度及使用電壓測試 53 3-1-9 生物氣膠控制效率之研究方法 54 3-1-10 生物氣膠增進效率之評估方式 54 3-2 實驗計算方法與指標參數 55 第4章結果與討論 58 4-1 前置實驗測試結果 58 4-1-1 生物氣膠初始濃度及實驗艙生物氣膠濃度達穩定所需時間 58 4-1-2 決定生物氣膠採樣間隔及採樣時間 60 4-1-3 負離子產生單元所用放電電壓選擇及負離子空間分佈 62 4-2 生物氣膠剩餘率及控制效率 66 4-3 處理方法對壁面貼附材料控制生物氣膠的增進效率 77 4-3-1 負離子產生裝置對壁面貼附材料控制生物氣膠之增進效率 77 4-3-2 壁面貼附材料噴附奈米矽片銀控制生物氣膠 82 4-4 壁面貼附材料對負離子控制生物氣膠的增進效率 87 4-5 小結 95 第5章結論與建議 102 5-1 結論 102 5-2 建議 105 參考文獻 107
dc.language.iso	zh-TW
dc.title	壁面貼附材料與空氣負離子對室內生物氣膠控制效率的影響	zh_TW
dc.title	Control Effectiveness of Wall Surface Materials and Negative Air Ion on Indoor Bioaerosols	en
dc.type	Thesis
dc.date.schoolyear	100-2
dc.description.degree	碩士
dc.contributor.oralexamcommittee	張靜文(Ching-Wen Chang),黃小林(Hsiao-Lin Huang),楊心豪(Shin-Hao Yang)
dc.subject.keyword	生物氣膠,空氣負離子,奈米矽片銀,壁面貼附材質,控制效率,增進效率,	zh_TW
dc.subject.keyword	bioaerosols,negative air ions,AgNPs/NSP,PP-filter,control efficiency,enhanced efficiency,	en
dc.relation.page	117
dc.rights.note	同意授權(全球公開)
dc.date.accepted	2012-08-15
dc.contributor.author-college	工學院	zh_TW
dc.contributor.author-dept	環境工程學研究所	zh_TW
顯示於系所單位：	環境工程學研究所

文件中的檔案：

檔案	大小	格式
ntu-101-1.pdf	2.73 MB	Adobe PDF	檢視/開啟

顯示文件簡單紀錄

系統中的文件，除了特別指名其著作權條款之外，均受到著作權保護，並且保留所有的權利。